Ketones, reductive cleavage nitriles

The reductive capability of CgK has been a subject of interest (LA). Uses for CgK include the reductive cleavage of carbon-sulfur bonds (S5), the reductive alkylation of nitriles and esters (S6), and the reductive alkylation of aldehydes and ketones (S7). The activity of CgK has... 

Burk et al. showed the enantioselective hydrogenation of a broad range of N-acylhydrazones 146 to occur readily with [Et-DuPhos Rh(COD)]OTf [14]. The reaction was found to be extremely chemoselective, with little or no reduction of alkenes, alkynes, ketones, aldehydes, esters, nitriles, imines, carbon-halogen, or nitro groups occurring. Excellent enantioselectivities were achieved (88-97% ee) at reasonable rates (TOF up to 500 h ) under very mild conditions (4 bar H2, 20°C). The products from these reactions could be easily converted into chiral amines or a-amino acids by cleavage of the N-N bond with samarium diiodide. 

This chapter deals mainly with the 1,3-dipolar cycloaddition reactions of three 1,3-dipoles azomethine ylides, nitrile oxides, and nitrones. These three have been relatively well investigated, and examples of external reagent-mediated stereocontrolled cycloadditions of other 1,3-dipoles are quite limited. Both nitrile oxides and nitrones are 1,3-dipoles whose cycloaddition reactions with alkene dipolarophiles produce 2-isoxazolines and isoxazolidines, their dihydro derivatives. These two heterocycles have long been used as intermediates in a variety of synthetic applications because their rich functionality. When subjected to reductive cleavage of the N—O bonds of these heterocycles, for example, important building blocks such as p-hydroxy ketones (aldols), a,p-unsaturated ketones, y-amino alcohols, and so on are produced (7-12). Stereocontrolled and/or enantiocontrolled cycloadditions of nitrones are the most widely developed (6,13). Examples of enantioselective Lewis acid catalyzed 1,3-dipolar cycloadditions are summarized by J0rgensen in Chapter 12 of this book, and will not be discussed further here. 

Dipolar cycloaddition reactions between nitrile oxides and aUcenes produce 2-isoxazolines. Through reductive cleavage of the N—O bond of the 2-isoxazohnes, the resulting heterocycles can be readily transformed into a variety of important synthetic intermediates such as p-hydroxy ketones (aldols), p-hydroxy esters, a,p-unsaturated carbonyl compounds, y-amino alcohols, imino ketones and so forth (7-12). 

Trifluoropropcnc itself reacts regioselectively with various nitrile oxides, even nonaromatic nitrile oxides. The latter arc prepared in one step from oximes and A -chlorosuccin-imide, or in a two-step sequence with isolation of the hydroximoyl chlorides. Cycloadducts, obtained at room temperature in the presence of triethylamine, are then converted into trilluoro- 8-hydroxy ketones 9 by reductive cleavage. The reaction with a dipole substituted by a group derived from L-phcnylalanine allows the preparation of chiral ketones. ... 

Since utilization of the ketone carbonyl was now complete, its removal was implemented via an efficient three-step sequence involving reductive cleavage of the derived selenocarbonate with tris(trimethylsilyl)silane [12] under free radical conditions [13]. With the acquisition of 17 in this manner, the serviceability of the reagent produced by adding sodium borohydride to cobaltous chloride for chemoselective reduction of the nitrile group [14] was assessed. Indeed, treatment of 17 in this manner, followed directly by basification with potassium hydroxide in methanol, secured 18. In this step as well as in the subsequent progression to the N-methyl derivative 19, no epimerization was seen within ring A. 

Graphite reacts with alkali metals - potassium, cesium and rubidium - to form lamellar compounds with different stoichiometries. The most widely known intercalate is the potassium-graphite which has the stoichiometry of CgK. In this intercalate the space between the graphite layers is occupied by K atoms. CgK functions as a reducing agent in various reactions such as reduction of double bonds in a,fl-unsaturated ketones [19], carboxylic acids and Schiff bases alkylation of nitriles [20], esters and imines [21] reductive cleavage of carbon-sulfur bonds in vinylic and allylic sulfones [22]. The detailed reaction mechanism of CgK is not known, and the special properties which are ascribed to the intercalate come either from the equilibrium between K+/K [23], or topochemical observations (the layer structure) [24]. 

Nickel-bpy and nickel-pyridine catalytic systems have been applied to numerous electroreductive reactions,202 such as synthesis of ketones by heterocoupling of acyl and benzyl halides,210,213 addition of aryl bromides to activated alkenes,212,214 synthesis of conjugated dienes, unsaturated esters, ketones, and nitriles by homo- and cross-coupling involving alkenyl halides,215 reductive polymerization of aromatic and heteroaromatic dibromides,216-221 or cleavage of the C-0 bond in allyl ethers.222... 

Q , 8-Ethylenic sulfones exhibit a behavior that could be considered as specific and totally different from that of Q , 8-ethylenic ketones or nitriles. Thus, with the present series, there is practically no case of dimerization or double-bond saturation. This seems to be because of the fact that reduction of compounds of this series cannot be completed neither in acidic nor in aqueous solutions because a fast cleavage occurs at the level of the anion radical. 

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